Method of repairing leakage in pipelines

ABSTRACT

A method of repairing leakage in pipelines comprising the steps of forming a first and second openings ( 14   a,    14   b ) in the pipeline ( 10 ) upstream and downstream, respectively, of the leakage location, inserting through the first opening ( 14   a ) a first body (C 1 ), filling the space arrear of the first body (C 1 ) with a first viscose sealing material (M 1 ), inserting through the first opening ( 14   a ) a second body (C 2 ) arrear of the first viscose sealing material (M 1 ) compressing the first sealing material by applying a pressure against the first and the second bodies (C 1,  C 2 ) in opposite directions, causing the first and second bodies (C 1,  C 2 ) and the compressed first sealing material (M 1 ) to move in unison in the direction of the second opening ( 14   b ), and retrieving the first and second bodies (C 1,  C 2 ). Preferably, the method is performed using three bodies (C 1,  C 2,  C 3 ) and two sealing materials (M 1,  M 2 ).

FIELD OF THE INVENTION

The present invention relates to the repair or restoration of local cracks in pipes, in particular of large diameter water, fuel or gas underground pipelines. More specifically the invention concerns the repair of such pipes when the exact site to be repaired is either unknown or unreachable.

BACKGROUND OF THE INVENTION

In order to conduct water, fuel or gas over large distances, pipelines that span immense lengths are installed. Occasionally, due to corrosion or other different wearing processes, small cracks might occur in the pipes, resulting in a leakage of the fluid that flows through the pipe. Since the pressure in such pipes may reach up to 100 at., the fluid is rapidly lost into the soil.

A leakage is usually discovered by a sharp pressure-drop, or by the recognition of a stain over the leakage location, indicating that a large amount of the fluid has already been lost. Besides the environment-harming aspect, such leakages may cause the loss of thousands of dollars per hour.

The repair of underground pipelines poses a series of complicated technological problems considering the relevant factors, mainly, difficult accessibility to the damaged part of the pipelines if welding or complete replacement thereof needs to be applied. This is particularly true when considering pipelines that are thousand of kilometers long or pipelines that lay underneath buildings and roads.

Also due to the high pressure prevailing in the pipeline, the use of simple adhesives and other common sealing agents had to be ruled-out.

The closest prior art known to applicants is Russian Patent No. 2063273 (Appin. No. 92007181/26 filed Nov. 23, 1992), describing a method of in-situ repair (namely from the inside of the pipe), by injecting specific chemical substances from both sides of the damaged location.

It is the prime object of the present invention to provide a more efficient method of in-situ repair of pipelines.

It is a further object of the invention that the actual repair process be completed instantly, reducing to a minimum the time period during which the flow through the pipeline must be discontinued.

It is a still further object of the invention to offer one or more sealing agents formulations especially suitable for the purposes the invention herein disclosed.

SUMMARY OF THE INVENTION

According to the invention there is provided a method of repairing leakage in pipelines comprising the steps of forming a first opening in the pipeline upstream of the leakage location, forming a second opening in the pipeline downstream of the leakage location, inserting through the first opening a first body, conforming the size of the pipeline, into the pipeline downstream of the first opening, filling the space arrear of the first body with a first viscose sealing material, inserting through the first opening a second body conforming the size of the pipeline into the pipeline arrear of the first viscose sealing material, compressing the first sealing material by applying a pressure against the first and the second bodies in opposite directions, causing the first body, the compressed first sealing material and the second body to move in unison in the direction of the second opening, and retrieving the first and second bodies from the pipeline through the second opening.

The method preferably comprises the further steps of filling the space an⁻ear of the second body with a second viscose sealing material, inserting through the first opening a third body, conforming the size of the pipeline, into the pipeline arrear of the second viscose sealing material, compressing the first and second sealing materials by applying a pressure against the first and the third bodies in opposite directions, causing the first body, the compressed first sealing material, the second body, the compressed second sealing material, and the third body to move in unison in the direction of the second opening, and retrieving the first, second and third bodies from the pipeline through the second opening.

The said bodies are preferably spherical, made of a semi-rigid material such as Polyurethane.

BRIEF DESCRIPTION OF THE DRAWINGS

These and additional constructional features and advantages of the present invention will become more readily understood in the light of the ensuing description of preferred embodiments thereof, given by way of example only, with reference to the accompanying drawings, wherein—

FIG. 1 is a schematic layout of a typical pipeline with a leaking portion and including a preparatory stage of the repair method according to a preferred embodiment of the present invention;

FIGS. 2 a-2 g represent further steps of the method; and

FIGS. 3 a and 3 b illustrate a way of nesting the respective sealing materials in their desired locations.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

In FIG. 1 there is shown a length of pipeline 10 buried in ground G. Anywhere upstream of the pipeline 10 there is provided a shutting valve 12.

A leaking location L has been identified, typically due to a hole or a crack H caused by excessive corrosion developed over many years of use.

The first stage of the repairing method consists of shutting-off the flow in the pipe by the valve 12 and digging-away the ground over the pipe at two distanced locations A and B at both sides of the leaking location L. The distances A to L and B to L need not be equal, and in fact selected according to the accessibility conditions which may change from one site to another.

At each location A and B, the pipe is torch-cut so as to form a first circular opening 14 a, and a second circular opening 14 b, respectively, both of a diameter equal to that of the pipe 10. Up-rise pipe sections (“manholes”) 16 a and 16 b are welded or otherwise affixed to the pipe 10, as shown.

In the next stage (FIG. 2 a), a first spherical body C1 is inserted through the manhole 16 a down into the pipe 10. Right thereafter a viscose sealing material M1, the chemical formula of which will be given below, is filled into the pipe, followed by a second spherical body, C2 (FIG. 2 b). The bodies C1 and C2 acting as pistons, are preferably made of a semi-rigid material such as Polyurethane so that they may easily pass through the pipe which may have bumps and protrusions along its inner surface.

It should be emphasized at this stage that the sealing method as proposed according to the present invention can be applied by using the spherical bodies C1 and C2 and a viscose sealing material M1 only, in the exact manner as will be described further below. However, it is highly preferable to use a combination of materials M1 and M2, which needs the introduction of a third spherical body C3, as depicted in FIG. 2 c. The advantages of this last-mentioned feature will be explained in detail below.

Whether or not the option of FIG. 2 c is adopted, the material M1 (as well as M2) should be compressed during the repair process to allow its penetration into the crack/hole H.

To this end, pressure should be applied from both sides of the array C2-M1-C1 (or C3-M2-C2-M1-C1). For this purpose, as seen in FIG. 2 d, the manholes 16 a and 16 b are closed and a pressurized fluid or gas is pumped into the pipe 10 in order to press the bodies C1, C2 and C3 one against the other and hence compact the materials M1 and M2.

It is further requested that the pressure P₁ applied from 16 a be somewhat greater then that P₂ applied from the opposite side, which pressure difference will cause the propagation of the array C3-M2-C2-M1-C1 in unison, in the direction of the manhole 16 b.

The amount of pressure P₂ that should be applied against the array is preferably given by the formula:

P ₂ ≦a−b/D

wherein: P₂—pressure (bar); a—an empirical factor that varies between 2.5 and 3.5; b—an empirical factor that varies between 0.035 and 0.045; and D—diameter of the pipe (meters).

During the travel of the array, as shown in FIG. 2 d and FIG. 2 e, there will be formed on the inside surface of the pipe 10, including the crack H, a first layer of the material M1, and over it a second layer of the material M2. A chemical interaction between these two layers will bring to the solidification of their combination and assure the complete, durable filling of the crack H (see below).

In the further stage (FIG. 2 f) the bodies C1 and C2 (and C3—if applicable) are retrieved through the manhole 16 b.

The pipe sections 16 a and 16 b are then removed and replaced by covers 18 a and 18 b of any conventional type (FIG. 2 g).

According to a preferred embodiment of this invention (FIG. 3 a), in order to prevent their spreading away in different directions while passing from the manhole 16 a into the pipe 10, the materials M1 and M2 are supplied in bags K1 and K2, respectively.

The bags are preferably made of a readily tearable sheet material, such as cellophane or polyethylene, so that they become ruptured when pressure is applied to the array from both sides (FIG. 3 b). Upon the tearing of the bags, the materials will intensively contact and wet the inner surface of the pipe and penetrate the cracks once reaching them.

Let us now turn to the specification of the materials recommended according to an additional aspect of the present invention.

In an embodiment wherein only one sealing material M1 is employed, the material should be selected from the group of conventional hardeners.

In the preferred embodiment, according to which two materials M1 and M2 are used, the materials may consist of a mix of a compound A, a hardener B a softener S, a filler mineral Z an elastic filler E and a hard filler D, wherein:

-   A is an organic polycondensate compound; -   B is a hardener such as phenylenediamine or diamino-difenylsulfone; -   S is a softener such as dibutyl phthalate or diphenyl phthalate; -   Z is a filler mineral such as ash of granular size ranging between 2     to 15 microns; -   E is an elastic filler such as the commercially known “Isoltherm™”     (described in U.S. Pat. No. 6,057,378) of size ranging between 4 to     7 millimeters; and -   D is a hard filler such as granules of nylon of size ranging between     1 to 4 millimeters.

The proportional amount of each of the components regarding the respective materials is given below (in weight parts).

Material M1

100 units of component A, 0-10 units of component S, 110-130 units of component Z, and component B, the amount of which is given by the formula:

B=A*λ−K ₁

Wherein:

K₁—an empirical factor that varies between 0 and 25; and λ—an empirical factor that varies between 02-0.45.

Material M2

20-60 units of component A, 0-10 units of component S, 50-100 units of component Z and component B, the amount of which is given by the formula:

B=A*λ+K ₂

Wherein:

K₂—an empirical factor that varies between 0 and 30; and λ—an empirical factor that varies between 02-0.45.

Additionally, material M2 should contain 10-15 units of component E and 5-10 units of component D that are meant to penetrate the crack together with material M2 and create a partial barrier between the filling materials and the fluid upon restarting of the flow in the pipe, so that the filling will not become washed away.

The total amount of the sealing materials that should be injected between two adjacent spherical bodies is given by the formula:

G≧ρD

wherein: G—quantity (tons); ρ—an empirical factor that varies between 1 and 1.2; and D—internal diameter of the pipe (meters).

The time that will take for the combination of the materials M1 and M2 to solidify is expected to follow the formula:

T≧γLD

Wherein:

T—time (hours); γ—an empirical factor that varies between 2.5 and 15; L—length of pipe (kilometers); and D—internal diameter of the pipe (meters).

After that period of time it will be safe to renew the flow through the pipe without the danger of washing away the se& layer.

In order to achieve optimal results in regard to the solidification of the combination of these two materials, according to a preferable embodiment, the first material M1 should contain a certain amount of material M2, and the material M2 should contain a certain amount of material M1. This could be achieved either by simply mixing all the ingredients together or by using capsules that contain M1 and M2 and inserting them into the bags of M2 or MI., respectively, so that when material M1 is pushed into the crack, the capsules will break and release a preset quantity of the material M2.

While the invention as herein described includes numerous specifics it should be readily apprehended by those skilled in the art to which the invention pertains that the scope thereof should not be limited by such specifics but rather in and by the appended claims. 

What is claimed is:
 1. A sealing agent formulation for in situ repair of a pipeline, the sealing agent formulation comprising a first viscous sealing material, wherein said sealing agent formulation is formulated to (i) be compressed under pressure and to penetrate, seal, and solidify in at least one of a hole and a crack in said pipeline, and (ii) provide durable filling of said at least one of said hole and said crack to provide the in situ repair thereof.
 2. The sealing agent formulation according to claim 1, further comprising a second viscous sealing material.
 3. The sealing agent formulation according to claim 2, wherein each of the first and second viscous sealing materials comprises a mix of at least three constituent materials selected from the group consisting of an organic polycondensate compound, a hardener, a softener, a filler mineral, an elastic filler, and a hard filler.
 4. The sealing agent formulation according to claim 1, wherein the first viscous sealing material comprises a hardener selected from the group consisting of phenylenediamine, and diamino-diphenylsulfone.
 5. The sealing agent formulation according to claim 1, wherein the first viscous sealing material comprises an organic polycondensate compound.
 6. The sealing agent formulation according to claim 1, wherein the first viscous sealing material comprises a softener selected from the group consisting of dibuthylphtalate, and diphenylphtalate.
 7. The sealing agent formulation according to claim 1, wherein the first viscous sealing material comprises a filler material that includes particles having a particle size between 2 and 15 microns.
 8. The sealing agent formulation according to claim 1, wherein the first viscous sealing material comprises an elastic filler that includes particles having a particle size between 4 and 7 millimeters.
 9. The sealing agent formulation according to claim 8, wherein said elastic filler is Isoltherm™.
 10. The sealing agent formulation according to claim 1, wherein said first viscous sealing material comprises: 100 units by weight of an organic polycondensate compound; 0 to 10 units by weight of a softener; and 110 to 130 units by weight of a ground filler material.
 11. The sealing agent formulation according to claim 10, wherein said first viscous sealing material further comprises a hardener, an amount B₁ of which (in units by weight) is given by a formula B₁=A₁λ+K₁, where A₁ is an amount (in units by weight) of the organic polycondensate compound in the first viscous sealing material, λ is an empirical factor between 0.2 and 0.45, and K₁ is an empirical factor between 0 and
 25. 12. The sealing agent formulation according to claim 2, wherein said second viscous sealing material comprises: 20 to 60 units by weight of an organic polycondensate compound; 0 to 10 units by weight of a softener; 50 to 100 units by weight of a ground filler material; a hardener; and an elastic filler.
 13. The sealing agent formulation according to claim 12, wherein an amount B₂ (in units by weight) of the hardener in the second viscous sealing material is given by a formula B₂=A₂λ+K₂, where A₂ is an amount (in units by weight) of the organic polycondensate compound in the second viscous sealing material, A is an empirical factor between 0.2 and 0.45, and K₂ is an empirical factor between 0 and
 30. 14. The sealing agent formulation according to claim 12, wherein an amount of the elastic filler in the second viscous sealing material is 10-15 units by weight.
 15. The sealing agent formulation according to claim 12, wherein the second viscous sealing material further comprises a hard filler.
 16. The sealing agent formulation according to claim 12, wherein an amount of the hard filler in the second viscous sealing material is 5-10 units by weight.
 17. An array for use in sealing a pipeline, the array comprising a first spherical body, a second spherical body, and a first viscous sealing material disposed between the first and second spherical bodies.
 18. The array of claim 17, further comprising a third spherical body, and a second viscous sealing material disposed between the second and third spherical bodies.
 19. A method for in situ repair of leakage in a pipeline, the method comprising: providing an array comprising two spherical bodies with a first viscous sealing material disposed therebetween; introducing the array into a pipeline; introducing a pressurized liquid or gas into the pipeline to apply a first pressure to a first side of the array; and introducing a pressurized liquid or gas into the pipeline to apply a second pressure to a second, opposing side of the array to compress said sealing agent formulation, wherein the first pressure and the second pressure are unequal, thereby causing propagation of the array towards the leakage, such that the first viscous sealing material enters a crack or hole causing the leakage and solidifies therein to provide durable filling of the crack or hole in said pipeline to repair the leakage.
 20. A method for in situ repair of leakage in a pipeline, the method comprising: providing an array comprising a first spherical body, a second spherical body, a third spherical body, a first viscous sealing material disposed between the first and second spherical bodies, and a second viscous sealing material disposed between the second and third spherical bodies; introducing the array into a pipeline; introducing a pressurized liquid or gas into the pipeline to apply a first pressure to a first side of the array; and introducing a pressurized liquid or gas into the pipeline to apply a second pressure to a second, opposing side of the array to compress said sealing agent formulation, wherein the first pressure and the second pressure are unequal, thereby causing propagation of the array towards the leakage, such that the first viscous sealing material, and then the second viscous sealing material enters a crack or hole causing the leakage and forms a mixture, the mixture solidifying therein to provide durable filling of the crack or hole in said pipeline to repair the leakage. 